An autonomous flow control device with pilot amplification includes a primary valve responsive to changes in fluid composition, and a pilot valve responsive to and more sensitive to changes in fluid composition than the primary valve and configured to aid change in position of the primary valve in the event of a change in fluid composition.

A fill valve for receiving a fluid flow includes a lower pipe and a flow restrictor cartridge. The flow restrictor cartridge is received in the lower pipe. The flow restrictor cartridge receives the fluid flow at a first fluid flow rate and provides the fluid flow as a second fluid flow rate lower than the first fluid flow rate. The flow restrictor cartridge includes a receiver and a compact flow restrictor. The compact flow restrictor is received by the receiver. The compact flow restrictor is configured to facilitate the reduction from the first fluid flow rate to the second fluid flow rate.

An expansion valve (1) for a vapour compression system, the valve (1) comprising a first valve part (5) having an outlet orifice (7) and a piston (8) movable inside the outlet orifice (7) in response to a differential pressure across the expansion valve (1), controlling a fluid flow through the first valve part (5). A cross-sectional flow area of the outlet orifice (7) between a circumference at an inner surface of the outlet orifice (7) and a circumference at an outer surface of the piston (8) varies as a function of the position of the piston (8) relative to the outlet orifice (7). A first cross-sectional flow area is defined at a first differential pressure, and a second cross-sectional flow area is defined at a second differential pressure, where the first cross-sectional flow area is smaller than the second cross-sectional flow area, and the first differential pressure is lower than the second differential pressure.

An expansion valve (1) for a vapour compression system, the valve comprising a first valve part (5) having an outlet orifice (7) and a piston (8) movable inside the outlet orifice (7) in response to a differential pressure across the expansion valve (1), controlling a fluid flow through the first valve part (5), via a forward fluid passage through the first valve part (5). The piston (8) has different cylindrical shapes stepwise along a longitudinal extension of the piston (8), the piston (8) defining a first cross-sectional area along a first longitudinal extension and a second-cross sectional area along a second longitudinal extension, the first cross-sectional area being smaller than the second-cross sectional area. The first longitudinal extension is in the outlet orifice (7) at a first differential pressure and the second longitudinal extension is in the outlet orifice (7) at a second differential pressure, the first differential pressure being lower than the second differential pressure.

The invention relates to a system, particularly for vegetation cultivation, including a water reserve, a device for controlling the flow towards the exterior of the volume contained in the reserve, including a floating regulator placed in the reserve to monitor the level thereof, which floating regulator defines a chamber having at least one upper inlet orifice in fluidic communication with the reserve volume, at least one lower calibrated outlet orifice of reduced section in communication with the exterior, such that the floating regulator allows a discharge of water towards the exterior via the outlet orifice at constant flow rate as long as the water level in the reserve is above the height of the inlet orifice and interrupts the discharge of water towards the exterior via the outlet orifice when the water level is below the inlet orifice to then define a water reserve. The invention also relates to the floating regulator, the use thereof and/or of the system, and a water reserve control method.

An application for a flow control system includes a pressure vessel, positioned within the interior of a container which is fluidly interfaced to a downstream drainage system. The pressure vessel has at least one opening through its lower surface, through which it is slideably engaged over the exterior of a closed conduit which is in fluid communication with an upstream reservoir. There is no need for a seal between the pressure vessel and the closed conduit such that the interior of the pressure vessel is in fluid communication with the interior of the container. Additional openings, from the interior of the pressure vessel may also be provided. A means to restrain the pressure vessel from significant lateral movement is provided. As the fluid pressure rises in the pressure vessel in response to an increase in the fluid level in the upstream reservoir, the openings through the pressure vessel rise to prescribed level and the release rate of fluid into the downstream drainage system is maintained at a prescribed rate or range of rates as the fluid level continues to rise.

A technique facilitates regulation of flow through a flow control device to improve a well operation, such as a production operation. The technique utilizes a flow control device which has a valve positioned in a housing for movement between flow positions. The different flow positions allow different levels of flow through a primary flow port. At least one flow regulation element, e.g. a Venturi based flow regulation element, is used in a control line in communication with the valve to establish a differential pressure acting on the valve. The differential pressure is a function of fluid properties and is used to autonomously actuate the flow control device to an improved flow position.

A method of controlling fluid flow into a heavy oil production pipe is disclosed. The method involves reducing inflow into a production pipe locally from hot spots using inflow control devices comprising a movable body provided within a housing. The movable body is arranged to adjust the flow of fluid through the inflow control devices autonomously by exploiting the Bernoulli principle. Inflow into the production pipe remote from said hot spots may be increased using the inflow control devices to increase inflow locally, and draw down in said production pipe may be increased by using an injector to inject a gaseous medium at or downstream of said inflow control devices.

A pressure reduction system for supplying fluid from a pressurized source to a hand operated pump, such as a pitcher pump or similar style manual pump, is disclosed. The system regulates the pressurized fluid from the source so that only the desired amount of fluid at substantially atmospheric pressure is supplied to the hand pump inlet when needed or called for by the pump.